AC light emitting diode and AC LED drive methods and apparatus

ABSTRACT

An LED device for use with an AC voltage power source configured such that at least one LED emits light during a positive phase of power provided from an AC power supply and at least one LED emits light during the negative phase of power provided from an AC power supply. The LED device includes a first power connection lead and a second power connection lead, both leads capable of being connected to and receiving power from an AC power supply.

RELATED APPLICATIONS

The present application is a continuation of U.S. patent applicationSer. No. 16/407,076 filed May 8, 2019, which is a continuation of U.S.patent application Ser. No. 16/148,945 filed Oct. 1, 2018, which is acontinuation of U.S. patent application Ser. No. 15/334,029 filed Oct.25, 2016, which is continuation-in-part of U.S. patent application Ser.No. 14/948,635 filed Nov. 23, 2015, which is a divisional application ofU.S. patent application Ser. No. 13/697,646 filed Nov. 13, 2012 which isa 371 National Phase Application of International Application No.PCT/US2011/0363359 filed May 12, 2011 which claims priority to U.S.Provisional Application No. 61/333,963 filed May 12, 2010 and is acontinuation-in-part of International Application No. PCT/US2010/062235filed Dec. 28, 2010 which claims priority to U.S. ProvisionalApplication No. 61/284,927 filed Dec. 28, 2009 and U.S. ProvisionalApplication No. 61/335,069 filed Dec. 31, 2009 and is acontinuation-in-part of U.S. patent application Ser. No. 12/287,267,filed Oct. 6, 2008, which claims priority to U.S. ProvisionalApplication No. 60/997,771, filed Oct. 6, 2007; U.S. patent applicationSer. No. 12/364,890 filed Feb. 3, 2009 which is a continuation of U.S.application Ser. No. 11/066,414 (now U.S. Pat. No. 7,489,086) filed Feb.25, 2005 which claims priority to U.S. Provisional Application No.60/547,653 filed Feb. 25, 2004 and U.S. Provisional Application No.60/559,867 filed Apr. 6, 2004; International Application No.PCT/US2010/001597 filed May 28, 2010 which is a continuation-in-part ofU.S. application Ser. No. 12/287,267, and claims priority to U.S.Provisional Application No. 61/217,215, filed May 28, 2009;International Application No. PCT/US2010/001269 filed Apr. 30, 2010which is a continuation-in-part of U.S. application Ser. No. 12/287,267,and claims priority to U.S. Provisional Application No. 61/215,144,filed May 1, 2009; the contents of each of these applications areexpressly incorporated herein by reference.

TECHNICAL FIELD

The present invention generally relates to light emitting diodes(“LEDs”) and LED drivers. The present invention specifically relates toalternating current (“AC”) driven LEDs, LED circuits and AC drivecircuits and methods.

FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

None.

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention generally relates to light emitting diodes(“LEDs”) and LED drivers. The present invention specifically relates toalternating current (“AC”) driven LEDs, LED circuits and AC drivecircuits and methods.

2. Description of the Related Art

LEDs are semiconductor devices that produce light when a current issupplied to them. LEDs are intrinsically DC devices that only passcurrent in one polarity and historically have been driven by DC voltagesources using resistors, current regulators and voltage regulators tolimit the voltage and current delivered to the LED. Some LEDs haveresistors built into the LED package providing a higher voltage LEDtypically driven with 5V DC or 12V DC.

With proper design considerations LEDs may be driven more efficientlywith AC than with DC drive schemes. LED based lighting may be used forgeneral lighting, specialty lighting, signs and decoration such as forChristmas tree lighting. For example, U.S. Pat. No. 5,495,147 entitledLED LIGHT STRING SYSTEM to Lanzisera (hereinafter “Lanzisera”) and U.S.Pat. No. 4,984,999 entitled STRING OF LIGHTS SPECIFICATION to Leake(hereinafter “Leake”) describes different forms of LED based lightstrings. In both Lanzisera and Leake, exemplary light strings aredescribed employing purely parallel wiring of discrete LED lamps using astep-down transformer and rectifier power conversion scheme. This typeof LED light string converts input electrical power, usually assumed tobe the common U.S. household power of 110 VAC, to a low voltage,rectified to nearly DC input.

Pat. Pending Application No. 0015968A1 entitled PREFERRED EMBODIMENT TOLED LIGHT STRING to Allen (hereinafter “Allen”) discloses AC poweredLED-based light strings. Allen describes LED light strings employingseries parallel blocks with a voltage matching requirement for direct ACdrive placing fundamental restrictions on the number of diodes (LEDs) oneach diode series block, depending on the types of diodes used. Allendiscloses that for the forward voltage to be “matched,” in each seriesblock, the peak input voltage must be less than or equal to the sum ofthe maximum forward voltages for each series block in order to preventover-driving.

LEDs can be operated from an AC source more efficiently if they areconnected in an “opposing parallel” configuration as shown by WO98/02020and JP11/330561. More efficient LED lighting systems can be designedusing high frequency AC drivers as shown by Patent Publication Number20030122502 entitled Light Emitting Diode Driver (“Clauberg et. al.”)Clauberg et. al. discloses that higher frequency inverters may be usedto drive an opposing parallel LED pair, an opposing parallel LED stringand/or an opposing parallel LED matrix by coupling the LEDs to a highfrequency inverter through a resonant impedance circuit that includes afirst capacitor coupled in series to one or more inductors with theimpedance circuit coupled in series to opposing parallel LEDs with eachset of LEDs having a second series capacitor in series to the impedancecircuit. In this system additional opposing parallel configurations ofLEDs with capacitors may not be added to or removed from the output ofthe driver without effecting the lumens output of the previouslyconnected LED circuits unless the driver or components at the driverand/or the opposing parallel LED capacitors were replaced with propervalues. By adding or removing the opposing parallel LED circuits thevoltage would increase or drop at the inductor and the current wouldincrease or drop through the first series capacitor as the load changedtherefore the inductor and all capacitors or entire driver would need tobe replaced or adjusted each time additional LEDs were added to orremoved from the system.

Patent application number US2004/0080941 entitled Light Emitting DiodesFor High AC Voltage Operation And General Lighting discloses that aplurality of opposing parallel series strings of LEDs can be integratedinto a single chip and driven with high voltage low frequency mains ACpower sources as long as there are enough LEDs in each opposing parallelseries string of LEDs to drop the total source voltage across the seriesLEDs within the chip. Patent numbers WO2004023568 and JP2004006582disclose that a plurality of opposing parallel series strings oropposing parallel series matrix of LEDs can be integrated into a singlechip and mounted on an insulating substrate and driven with a high drivevoltage and low drive current as long as there are enough LEDs in eachopposing parallel series string of LEDs to drop the total source voltageacross the series LEDs within the chip. These patents and applicationdisclose that for single chip or packaged LED circuits a plurality ofopposing parallel series strings are required with the total number ofLEDs in each series string needing to be equal to or greater than the ACvoltage source in order to drop the total forward voltage and providethe required drive current when driven direct with low frequency ACmains power sources.

The present invention addresses the above-noted shortcomings of theprior art while providing additional benefits and advantages

This invention continues the line of inventions of Nikola Tesla, andStanislav and Konstantin Avramenko. It is possible to transfer powerthrough one wire, even to operate an electric motor. It is also possibleto transfer power without any wires.

The self reference method and device goes one step ahead. For power andsignal applications there are benefits in using self referencingcircuits and devices without the need to bring extra objects todissipate the energy already in place or provide a DC return path toground or an AC power source. With precautions to protect integratedcircuits and low power electronic devices, it is possible to designefficient systems when the heat, energy and the error budgets areimportant. It is also possible to design solid state electric powertransformers that can be used in place of magnetic transformers. Byreducing the number of connections inside these systems, more efficientdesigns are possible. It is even conceivable to design portable systemswithout batteries. DC powered electronic devices require a magnetictransformer and rectification when powered with 120 volt or 240 volt ACpower. Additionally, they typically require a drop in supply voltage. Atransformer typically reduces the high voltage and rectifies it to DCcurrent. Solid state LED lighting can be powered with AC or DC dependingon the design on the device. If rectification is not required, resistorscan be used in place of a transformer to drop higher voltages. Theresistors generate heat and transformers can be cumbersome as well asgenerate heat.

One wire electric transmission is due to displacement currents. Thedipoles in matter and in the electromagnetic vacuum can move back andforth in the presence of a longitudinal alternating electric field. Apositive charge moving in the direction of the electric fieldcontributes equally to the current as a negative charge moving in theopposite direction. There does not have to be a net displacement ofcharge, from left to right say, to have an electric current. There is noneed for a return path.

There is no fundamental need to return all charges to a common dumpeither. One has to be careful not to produce intense electric fieldsthat break the stability of the material circuits, but beyond that,there is no need to return all charges to a big reservoir like theearth. For portable devices this is a good thing, otherwise they wouldbe impossible to construct. To perform all the tasks required, it isenough to have either real dipoles in material substances, or virtualdipoles in the electromagnetic vacuum. Once the function has beensatisfied, the device goes back to the state it had when the processstarted. Circuits according to the invention have one or more of thefollowing attributes: circulation/symmetry breaking/dipoles; differenceof time constant between charge and discharge; AC to DC rectification;tunable load to resonant frequency; frequency/voltage dependence; seriesinductance; series capacitance; and, an open system harnessingelectromagnetic field energy.

SUMMARY OF THE INVENTION

According to one broad aspect of the invention a lighting system isprovided having one or more LED circuits. Each LED circuit has at leasttwo diodes connected to each other in opposing parallel relation,wherein at least one of which such diodes is an LED. As used throughoutthe application, the term diode may mean any type of diode capable ofallowing current to pass in a single direction, including but notlimited to, a standard diode, a schottky diode, a zener diode, and acurrent limiting diode. A driver is connected to the one or more LEDcircuits, the driver providing an AC voltage and current to the one ormore LED circuits. The driver and the LED circuits form a drivencircuit. The driver and the LED circuits are also configured such thatLED circuits may be added to or subtracted (intentionally or bycomponent failure) from the driven circuit:

-   -   (a) without significantly affecting the pre-determined desired        output range of light from any individual LED; and,    -   (b) without the need to: (i) change the value of any discrete        component; or, (ii) to add or subtract any discrete components,        of any of the pre-existing driven circuit components which        remain after the change.

In another embodiment of the invention at least one capacitor isconnected to and part of each LED circuit. In yet another embodiment, atleast one resistor is connected to and is part of each opposing parallelLED circuit noted above. The resistor is connected in series with the atleast one capacitor.

According to another aspect of the invention an LED circuit (sometimesreferred to as an “AC LED”) can comprise two opposing parallel LEDs, anopposing parallel LED string or an opposing parallel LED matrix. Theseopposing parallel LEDs may have a capacitor in series connected to atleast one junction of the connected opposing parallel configurationswithin a single chip, a single package, an assembly or a module.

When a real capacitor is connected in series in one or more linesbetween an LED and an AC power source, there is a displacement currentthrough that capacity of magnitude: I=2ΠfCV. The capacitor in the LEDcircuits of the invention regulates the amount of current and forwardvoltage delivered to the one or more opposing parallel LEDs based on thevoltage and frequency provided by the AC driver. Based on the number ofLEDs in the LED circuit the opposing parallel connections provide two ormore junctions to which at least one series capacitor may be connectedin series of at least one power connection lead. In some embodiments,LED circuits may also use a series resistor in addition to the capacitorproviding an “RC” resistor capacitor network for certain LED circuitdriver coupling that does not provide protection against surge currentsto the LED circuits.

According to another aspect of the invention an LED circuit may comprisea single LED or a series string of diodes and/or LEDs connected to afull bridge rectifier capable of rectifying a provided AC voltage andcurrent for use by the series string of diodes and/or LEDs. Therectifier may be formed as part of the LED circuit, or may be formedseparately, having leads provided on both the output of the driver andthe input of the LED circuit to allow the LED circuit to connectdirectly to the driver. In order to protect the LED circuit from voltagespikes a capacitor may be connected across the inputs of the bridgerectifier. The capacitor may also be used for smoothing the AC waveformto reduce ripple. A capacitor may likewise be connected between onerectifier input and the AC voltage and current source in order to limitthe DC current flow to protect the LEDs. The bridge diode and LEDcircuit may be packaged separate or together, and may be configuredwithin a single chip or two chips, a single package or two packages, anassembly, or a module.

According to another aspect of the invention, a single bridge rectifiermay be used to drive parallel LEDs or series strings of diodes and/orLEDs. Alternatively, it is contemplated by the invention that each LEDcircuit requiring a bridge rectifier to utilize both the high and lowphases of an AC power wave may include its own full bridge rectifierintegrated or otherwise connected thereto. In embodiments where each LEDcircuit includes its own rectifier, additional LED circuits may be addedin parallel across an AC voltage and current source to any existing LEDcircuits without concern of connecting to any existing bridge rectifiersor, where used, capacitors. Providing each LED circuit with its ownbridge rectifier has the further advantage of scaling capacitorsincluded in the circuit for voltage protection and/or current limitingto be matched to a particular LED or string of diodes and/or LEDs.

It should be noted that “package” or “packaged” is defined herein as anintegrated unit meant to be used as a discrete component in either ofthe manufacture, assembly, installation, or modification of an LEDlighting device or system. Such a package includes LED's of desiredcharacteristics with capacitors and or resistors (when used) sizedrelative to the specifications of the chosen LED's to which they will beconnected in series and with respect to a predetermined AC voltage andfrequency.

Preferred embodiments of a package may include an insulating substratewhereon the LEDs, capacitors and/or resistors are formed or mounted. Insuch preferred embodiments of a package, the substrate will includeelectrodes or leads for uniform connection of the package to a device orsystem associated with an AC driver or power source or any individuallypackaged rectifiers used to rectify AC voltage and current. Theelectrodes, leads, and uniform connection may include any currentlyknown means including mechanical fit, and/or soldering. The substratemay be such as sapphire, silicon carbide, galium nitride, ceramics,printed circuit board material, or other materials for hosting circuitcomponents.

A package in certain applications may preferably also include a heatsink, a reflective material, a lens for directing light, phosphor,nano-chrystals or other light changing or enhancing substances. In sum,according to one aspect of the invention, the LED circuits and ACdrivers of the present invention permit pre-packaging of the LED portionof a lighting system to be used with standardized drivers (and whennecessary full wave rectifiers) of known specified voltage and frequencyoutput. Such packages can be of varied make up and can be combined witheach other to create desired systems given the scalable and compatiblearrangements possible with, and resulting from, the invention.

According to one aspect of the invention, AC driven LED circuits (or“driven circuits”) permit or enable lighting systems where LED circuitsmay be added to or subtracted (either by choice or by way of a failureof a diode) from the driven circuit without significantly affecting thepre-determined desired output range of light from any individual LEDand, without the need to: (i) change the value of any discretecomponent; or, (ii) to add or subtract any discrete components, of anyof the pre-existing driven circuit components which remain after thechange. During design of a lighting system, one attribute of the LEDschosen will be the amount of light provided during operation. In thiscontext, it should be understood that depending on the operatingparameters of the driver chosen, the stability or range of the voltageand frequency of the driver will vary from the nominal specificationbased upon various factors including but not limited to, the addition orsubtraction of the LED circuits to which it becomes connected ordisconnected. Accordingly, as sometimes referred to herein, driversaccording to the invention are described as providing “relativelyconstant” or “fixed” voltage and frequency. The extent of this relativerange may be considered in light of the acceptable range of light outputdesired from the resulting circuit at the before, during, or after achange has been made to the lighting system as a whole. Thus it will beexpected that a pre-determined range of desired light output will bedetermined within which the driven LED circuits of the invention willperform whether or not additional or different LED circuits have beenadded or taken out of the driven circuit as a whole or whetheradditional or different LED circuits have been added proximate anyexisting LED circuits or positioned remotely.

According to another aspect of the invention an LED circuit may be atleast one pre-packaged LED and one pre-packaged diode connected togetheropposing parallel of each other, two opposing parallel pre-packagedLEDs, an opposing parallel LED string of pre-packaged LEDs, an opposingparallel LED matrix of pre-packaged LEDs optionally having a capacitorin series of at least one junction of the connected LED circuits. It iscontemplated that the LED circuit may also be at least one of a singleLED or series string of diodes and/or LEDs having a bridge rectifierconnected across the the single LED or string of diodes. In embodimentswhere a series string of diodes and/or LEDs and a rectifier is utilized,each LED may likewise be pre-packaged. The rectifier may optionallyhaving a capacitor connected across the rectifier inputs and/or acapacitor connected between to an input of the rectifier for connectionbetween the rectifier and a AC voltage and current source. In eitherembodiment, utilizing an LED circuit capacitor may allow for directcoupling of at least one LED circuit to the LED driver withoutadditional series components such as capacitors and/or inductors betweenthe LED circuit driver and the LED circuits. The LED circuit driverprovides a relatively fixed voltage and relatively fixed frequency ACoutput even with changes to the load using feedback AC voltage regulatorcircuitry. The LED circuit's may be directly coupled and scaled inquantity to the LED circuit driver without affecting the other LEDcircuit's lumen output as long as the LED circuit driver maintains arelatively fixed voltage and relatively fixed frequency AC output.

According to an aspect of the invention, an LED circuit driver providesa relatively fixed voltage and relatively fixed frequency AC output suchas mains power sources. The LED circuit driver output voltage andfrequency delivered to the LED circuit may be higher than, lower than,or equal to mains power voltage and frequencies by using an LED circuitinverter driver. The LED circuit inverter driver providing higherfrequencies is preferable for LED circuits that are integrated intosmall form LED packages that include integrated capacitors or resistorcapacitor “RC” networks. The LED circuit inverter driver has feedbackcircuitry such as a resistor divider network or other means allowing itto sense changes to the load and re-adjust the frequency and/or voltageoutput of the LED circuit driver to a desired relatively fixed value.The LED circuit driver may also provide a soft-start feature thatreduces or eliminates any surge current from being delivered to the LEDcircuit when the LED circuit driver is turned on. Higher frequency andlower voltage LED circuit inverter drivers are preferred enablingsmaller package designs of LED circuits as the capacitor at higherfrequencies would be reduced in size making it easier to integrate intoa single LED circuit chip, package, assembly or module.

According to the invention LED circuits may have a resistor capacitor(“RC”) network connected together in series or separate from the the LEDcircuits. The maximum resistor value needed is only that value ofresistance needed to protect the one or more LEDs within the LED circuitfrom surge currents that may be delivered by LED circuit drivers that donot provide soft start or other anti surge current features. Directmains power coupling would require RC network type LED circuits as themains power source delivers surge currents when directly coupled to anLED circuit.

The higher frequency LED circuit inverter driver may be a halogen orhigh intensity discharge (HID) lamp type driver with designmodifications for providing a relatively fixed voltage and relativelyfixed frequency output as the LED circuit load changes. Meaning if theLED circuit inverter driver is designed to have an output voltage of 12Vat a frequency of 50 Khz the LED circuit driver would provide thisoutput as a relatively constant output to a load having one or more thanone LED circuits up to the wattage limit of the LED circuit driver evenif LED circuits were added to or removed from the output of the LEDcircuit driver.

The higher frequency inverter having a relatively fixed voltage andrelatively fixed frequency output allows for smaller components to beused and provides a known output providing a standard reference HighFrequency LED circuit driver enabling LED circuits to be manufactured involume in existing or reasonably similar LED package sizes withintegrated capacitors or RC networks based on the number of LEDs desiredin the LED circuit package.

Patent publication number 20030122502 entitled Light Emitting Diodedriver (Clauberg and Erhardt) does not disclose the use of a highfrequency inverter driver having a means or keeping a relatively fixedvoltage and relatively frequency in response to changes in the load.According to the present invention described herein, by not havingadditional components such as an inductor or capacitor in series betweenthe LED circuit and the LED circuit driver one LED circuit at a time maybe added to or removed from the LED circuit driver output without havingto change any components, the LED circuit driver or make adjustments tothe LED circuit driver. Additionally, according to this invention thelumen output of the existing LED circuits stays relatively constant dueto the self-regulating nature of each individual LED circuit when drivenwith the relatively fixed frequency and voltage of the LED circuitdriver. This level of scalability, single chip LED circuit packaging andstandardization is not possible with the prior art using an inductor inseries between the LEDs or other components due to the voltage orcurrent increase or drop across the inductors and capacitors in responseto changes in the load.

Prior art for single chip LED circuits, for example those disclosed inWO2004023568 and JP2004006582 do not provide a way to reduce the numberof LEDs within the chip below the total forward voltage droprequirements of the source. The present invention however, enables anLED circuit to be made with any number of LEDs within a single chip,package or module by using, where desired, transformers, capacitors, orRC networks to reduce the number of LEDs needed to as few as one singleLED. Improved reliability, integration, product and system scalabilityand solid state lighting design simplicity may be realized with LEDcircuits and the LED circuit drivers. Individual LED circuits being thesame or different colors, each requiring different forward voltages andcurrents may be driven from a single source LED circuit driver. Eachindividual LED circuit can self-regulate current by matching thecapacitor or RC network value of the LED circuit to the known relativelyfixed voltage and frequency of the LED circuit driver whether the LEDcircuit driver is a mains power source, a high frequency LED circuitdriver or other LED circuit driver capable of providing a relativelyfixed voltage and relatively fixed frequency output.

When a real capacitor is connected in series in one or more linesbetween an LED and an AC power source, there is a displacement currentthrough that capacity of magnitude: I=2ΠfCV. This means that one canpredetermine the amount of current to be delivered through a capacitancebased upon a known voltage and frequency of an AC source, allowing foreach LED circuit containing a series capacitor to have the specific orideal current required to provide the desired amount of light from theLED circuit.

According to other aspects of the invention, the LED circuit driver maybe coupled to a dimmer switch that regulates voltage or frequency or mayhave integrated circuitry that allows for adjustability of the otherwiserelatively fixed voltage and/or relatively fixed frequency output of theLED circuit driver. The LED circuits get brighter as the voltage and/orfrequency of the LED circuit driver output is increased to the LEDcircuits.

One form of the invention is at least one LED and one diode connectedtogether opposing parallel of each other, two opposing parallel LEDs, anopposing parallel LED string and/or opposing parallel LED matrix havinga capacitor in series of at least one connected junction of theconnected opposing parallel LED configurations within a single chip, asingle package, an assembly or a module. When desired, the LED circuitwith capacitor may be placed on an insulating substrates such as but notnecessarily ceramic or sapphire and/or within various LED package sizes;materials and designs based of product specifications or assembled onprinted circuit board material. Any integrated LED circuit capacitorsshould be scaled to a predetermined value enabling the LED circuit toself-regulate a reasonably constant and specific current when coupled toan LED circuit driver that provides a relatively fixed voltage andfrequency output. Utilized LED circuit capacitors may be of a valueneeded to provide the typical operating voltage and current of the LEDcircuit when designed for coupling to a specific LED circuit driver.

Another form of the invention is an LED circuit comprising at least oneLED and one diode connected together opposing parallel of each other,two opposing parallel LEDs, an opposing parallel LED string and/oropposing parallel LED matrix having a series resistor capacitor (“RC”)network connected together in series or independently in series betweenat least one connected junction of the opposing parallel LEDs and therespective power connection of the LED circuit. When desired, theopposing parallel LEDs and RC network may be placed on an insulatingsubstrate such as but not necessarily ceramic or sapphire and/or withinvarious LED package sizes; materials and designs based of productspecifications or assembled on printed circuit board material. The LEDcircuit RC network may be of a value needed to provide the typicaloperating voltage and current of the LED circuit when designed forcoupling to a specific LED circuit driver.

Another form of the invention is an LED circuit comprising a matrix oftwo opposing parallel LEDs connected together in parallel with every twoopposing parallel LEDs having an individual capacitor in series to thepower source connection if desired. The entire parallel array ofopposing parallel LED circuits, including capacitors when used, may bemay be placed on an insulating substrate such as but not necessarilyceramic or sapphire and/or within various LED package sizes; materialsand designs based of product specifications or assembled on printedcircuit board material. The opposing parallel matrix of LED circuitsintegrated in the LED circuit package may be RC network type LEDcircuits.

Another form of the invention is an LED circuit comprising a matrix ofopposing parallel LEDs connected together in parallel with every set ofopposing parallel LEDs having an individual RC network in series to thepower connection lead if desired.

Another form of the invention is an LED circuit comprising a matrix ofopposing parallel LEDs connected together in parallel, a capacitorconnected in series to at least one side of the line going to the matrixof opposing parallel LEDs with every set of opposing parallel LEDshaving an individual resistor in series to the power connection ifdesired.

Yet another form of the invention is an LED circuit comprising opposingparallel series strings of LEDs connected together and driven directwith a high frequency AC voltage equal to or less than to total seriesvoltage drop of the opposing parallel series strings of LEDs within theLED circuit.

Yet another form of the invention is a LED circuit comprising a singleLED or a series string of diodes and/or LEDs and a bridge rectifierconnected across the LED or string of diodes and/or LEDs. The rectifiermay optionally include a capacitor connected across the inputs of therectifier. The rectifier may additionally, or alternatively, optionallyinclude a capacitor connected in series with one input, the capacitorbeing capable of connecting the rectifier input to an AC voltage andcurrent source.

Yet another form of the invention is a LED circuit comprising a singleLEDs or a series strings of diodes and/or LEDs connected in parallelacross the output of a bridge rectifier. The rectifier may optionallyinclude a capacitor connected across the inputs of the rectifier. Therectifier may additionally, or alternatively, optionally include acapacitor connected in series with one input, the capacitor beingcapable of connecting the rectifier input to an AC voltage and currentsource.

Another form of the invention comprises a method of driving LED circuitsdirect from an AC power source (“LED circuit driver”) having arelatively fixed voltage and relatively fixed frequency. The LED circuitdriver may be a mains power source, the output of a transformer, agenerator or an inverter driver that provides a relatively fixed voltageand relatively fixed frequency as the load changes and may be a higheror lower frequency than the frequencies of mains power sources. The LEDcircuit driver provides a relatively fixed voltage and relatively fixedfrequency output even when one or more LED circuits are added to orremoved from the output of the LED circuit driver. Higher frequencyinverters with lower output voltages are used as one LED circuit driverin order to reduce component size and simplify manufacturing andstandardization of LED circuits through the availability of higherfrequency LED circuit drivers. The LED circuit driver may also includecircuitry that reduces or eliminates surge current offering a soft-startfeature by using MOSFET transistors, IGBT transistors or otherelectronic means. The LED circuit driver may also be pulsed outputs at ahigher or lower frequency than the primary frequency.

Another form of the invention is an LED lighting system comprising anLED circuit array having a plurality of different LED circuits eachdrawing the same or different currents, each having the same ordifferent forward operating voltages, and each delivering the same ordifferent lumen outputs that may be the same or different colors and anLED circuit driver coupled to the LED circuit array. The LED circuitdriver delivering a relatively fixed t frequency and voltage outputallows for mixing and matching of LED circuits requiring differentforward voltages and drive currents. The LED circuits may be connectedto the output of an LED circuit driver in parallel one LED circuit at atime within the limit of the wattage rating of the LED circuit driverwith no need to change or adjust the LED circuit driver as wouldtypically be required with DC drivers and LEDs when increasing orreducing the load with LEDs and other components. Never having to goback to the power source allows for more efficient integration andscalability of lighting systems designed with LED circuits and allowsfor a single driver to independently provide power to multipleindependently controlled LED circuits in the system. Introducing aninductor and/or an additional capacitor such as the impedance circuitdescribed in prior art between the LED circuit drive source and the LEDcircuits would require changes to the driver or components and prohibitscalability, standardization and mass production of AC-LEDs withintegrated capacitors or RC networks.

With the LED circuit driver providing a known relatively constant ACvoltage and frequency, mass production of various LED circuits withspecific capacitor or RC network values would deliver 20 mA, 150 mA or350 mA or any other desired current to the LED circuit based on theoutput of the specified LED circuit driver. The relatively fixed voltageand frequency allows for standardization of LED circuits through thestandardization of LED circuit drivers.

In another aspect, a transistor is coupled to at least one powerconnection of the LED circuit or built into the LED circuit package inseries between the power connection lead and the LED circuit with thetransistor being operable to control (e.g., varying or diverting) theflow of the alternating current through the LED circuit through acapacitance within the transistor.

The foregoing forms as well as other forms, features and advantages ofthe present invention will become further apparent from the followingdetailed description of the presently preferred embodiments, read inconjunction with the accompanying drawings. The detailed description anddrawings are merely illustrative of the present invention rather thanlimiting, the scope of the present invention being defined by theappended claims and equivalents thereof.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a schematic view of a preferred embodiment of theinvention.

FIG. 2 shows a schematic view of a preferred embodiment of theinvention.

FIG. 3 shows a schematic view of a preferred embodiment of theinvention.

FIG. 4 shows a schematic view of a preferred embodiment of theinvention.

FIG. 5 shows a schematic view of a preferred embodiment of theinvention.

FIG. 6 shows a schematic view of a preferred embodiment of theinvention.

FIG. 7 shows a schematic view of a preferred embodiment of theinvention.

FIG. 8 shows a schematic view of a preferred embodiment of theinvention.

FIG. 9 shows a schematic view of a preferred embodiment of theinvention.

FIG. 10 shows a schematic view of a preferred embodiment of theinvention.

FIG. 11 shows a schematic view of a preferred embodiment of theinvention.

FIG. 12 shows a schematic view of a preferred embodiment of theinvention.

FIG. 13 shows a schematic view of a preferred embodiment of theinvention.

FIG. 14 shows a schematic view of a preferred embodiment of theinvention.

FIG. 15 shows a schematic view of a preferred embodiment of the presentinvention.

FIG. 16 shows a schematic view of a preferred embodiment of the presentinvention.

FIG. 17 shows a schematic view of a preferred embodiment of the presentinvention.

FIG. 18 shows a schematic view of a preferred embodiment of the presentinvention.

FIG. 19 shows a schematic view of a preferred embodiment of theinvention.

FIG. 20 shows a schematic view of a preferred embodiment of theinvention.

FIG. 21 shows a schematic view of a preferred embodiment of theinvention.

FIG. 22 shows a schematic view of a preferred embodiment of theinvention.

FIG. 23 shows a schematic view of a preferred embodiment of theinvention.

FIG. 24 shows a schematic view of a preferred embodiment of the presentinvention.

FIG. 25 shows a schematic view of a preferred embodiment of the presentinvention.

FIG. 26 shows a schematic view of a preferred embodiment of the presentinvention.

FIG. 27 shows a schematic view of a preferred embodiment of the presentinvention.

FIG. 28 shows a schematic view of a preferred embodiment of the presentinvention.

FIG. 29 shows a schematic view of a preferred embodiment of theinvention.

FIG. 30A shows a schematic view of a preferred embodiment of theinvention.

FIG. 30B shows a schematic view of a preferred embodiment of theinvention.

FIG. 30C shows a schematic view of a preferred embodiment of theinvention.

FIG. 30D shows a schematic view of a preferred embodiment of theinvention.

FIG. 30E shows a schematic view of a preferred embodiment of theinvention.

FIG. 31 shows a schematic view of a preferred embodiment of theinvention.

FIG. 32 shows a schematic view of a preferred embodiment of theinvention.

FIG. 33 shows a schematic view of a preferred embodiment of theinvention.

FIG. 34 shows a schematic view of a preferred embodiment of theinvention.

FIG. 35 shows a schematic view of a preferred embodiment of theinvention.

FIG. 36 shows a schematic view of a preferred embodiment of theinvention.

FIG. 37 shows a schematic view of a preferred embodiment of theinvention.

FIG. 38 shows a schematic view of a preferred embodiment of theinvention.

FIG. 39 shows a schematic view of a preferred embodiment of theinvention.

FIG. 40 shows a schematic view of a preferred embodiment of theinvention.

FIG. 41 shows a schematic view of a preferred embodiment of theinvention.

FIG. 42 shows a schematic view of a preferred embodiment of theinvention.

FIG. 43 shows a schematic view of a preferred embodiment of theinvention.

FIG. 44 shows a schematic view of a preferred embodiment of theinvention.

FIG. 45 shows a schematic view of a preferred embodiment of theinvention.

FIG. 46 shows a schematic view of a preferred embodiment of theinvention.

FIG. 47 shows a schematic view of a preferred embodiment of theinvention.

FIG. 48 shows a schematic view of a preferred embodiment of theinvention.

FIG. 49 shows a schematic view of a preferred embodiment of theinvention.

FIG. 50 shows a schematic view of a preferred embodiment of theinvention.

FIG. 51 shows a schematic view of a preferred embodiment of theinvention.

FIG. 52 shows a schematic view of a preferred embodiment of theinvention.

FIG. 53 shows a schematic view of a preferred embodiment of theinvention.

FIG. 54 shows a schematic view of a preferred embodiment of theinvention.

FIG. 55 shows a schematic view of a preferred embodiment of theinvention.

FIG. 56 shows a schematic view of a preferred embodiment of theinvention.

FIG. 57 shows a schematic view of a preferred embodiment of theinvention.

FIG. 58 shows a schematic view of a preferred embodiment of theinvention.

FIG. 59 shows a schematic view of a preferred embodiment of theinvention.

FIG. 60 shows a schematic view of a preferred embodiment of theinvention.

FIG. 61 shows a schematic view of a preferred embodiment of theinvention.

FIG. 62 shows a schematic view of a preferred embodiment of theinvention.

FIG. 63 shows a schematic view of a preferred embodiment of theinvention.

FIG. 64 shows a schematic view of a preferred embodiment of theinvention.

FIG. 65 shows a schematic view of a preferred embodiment of theinvention.

FIG. 66 shows a schematic view of a preferred embodiment of theinvention.

FIG. 67 shows a schematic view of a preferred embodiment of theinvention.

FIG. 68 shows a schematic view of a preferred embodiment of theinvention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

While this invention is susceptible to embodiments in many differentforms, there is described in detail herein, preferred embodiments of theinvention with the understanding that the present disclosures are to beconsidered as exemplifications of the principles of the invention andare not intended to limit the broad aspects of the invention to theembodiments illustrated.

The present invention is directed to an LED light emitting device andLED light system capable of operating during both the positive andnegative phase of an AC power supply. In order to operate during bothphases provided by an AC power, as is shown herein, the circuit mustallow current to flow during both the positive and negative phases andLED light emitting devices may be configured such that at least one LEDis capable of emitting light during one or both of the positive ornegative phases. In order to accomplish this, the LED circuit itself maybe configured so as to allow current to pass during both phases, or thedevice may include a bridge rectifier to rectify AC power for use bysingle LEDs, series strings of LEDs, and parallel series strings ofLEDs. Rectification may be accomplished within the light emittingdevice, or prior to any power being provided to the same. Onceintegrated into a light system, the present invention furthercontemplates a driver having the ability to provide a substantiallyconstant voltage at a substantially constant frequency, and that thedriver be configured in a manner which will allow LED light emittingdevices to be added to or subtracted from the system, regardless ofconfiguration, without having to add, subtract, or change the values ofdiscrete circuit components and without affecting the light output ofany individual LED.

FIG. 1 discloses a schematic diagram of a light emitting device 10 foran AC driver according to one embodiment of the invention. The device 10includes a first LED 12 connected to a second LED 14 in opposingparallel configuration, a capacitor 16 connected in series between afirst junction 18 of the two opposing parallel LEDs, a first powerconnection 20 connected to the two opposing parallel LEDs, and a secondpower connection 22 connected to a second junction 24 of the twoopposing parallel connected LEDs. A diode may be used in place of LED 12or LED 14.

FIG. 2 discloses a schematic diagram of a light emitting device 26 foran LED circuit driver according to an embodiment of the invention. Thedevice 26 includes the device 10 as disclosed in FIG. 1 mounted on aninsulating substrate 28 such as, but not necessarily, ceramic orsapphire, and integrated into an LED package 30 that may be various LEDpackage sizes; materials and designs based of product specifications oron printed circuit board material. The device 26 provides powerconnection leads 32 and may have a first or additional lens 34 that maybe made of a plastic, polymer or other material used for lightdispersion and the lens may be coated or doped with a phosphor ornano-particle that would produce a change in the color or quality oflight emitted from the device 10 through the lens 34.

FIG. 3 discloses a schematic diagram of a device 36 having a schematicdiagram of the embodiment shown as light emitting device 26 drivendirectly by an AC driver 38 that is connected to the power connections32 of the device 26 without any additional components in series betweenthe AC driver 38 and the device 26 such as a capacitor, inductor orresistor. The AC driver 38 provides a relatively constant AC voltage andfrequency output to the device 26 no matter what the total load of thedevice 26 may be, or the number of devices 26 added or subtracted aslong as the load does not exceed the wattage limitation of the AC driver38. The AC driver 38 may be a generator, a mains power source, or aninverter capable of providing a relatively fixed voltage and relativelyfixed frequency output to different size loads. The AC driver mayprovide a low or high voltage and a low or high frequency to the device26 according to the invention as long as the capacitor 16 is the propervalue for the desired operation of the device 26.

FIG. 4 discloses a schematic diagram of a light emitting device 40 forcoupling to an LED circuit driver according to an embodiment of theinvention. The device 40 includes a first LED 42 connected to a secondLED 44 in opposing parallel configuration. A capacitor 46 is connectedin series between a first junction 48 of the two opposing parallel LEDsand a first power connection 50. A resistor 52 is connected in seriesbetween a second junction 54 of the two opposing parallel LEDs and asecond power connection 56. A diode may be used in place of LED 42 orLED 44 and the resistor 52 may be put in series on either end of thecapacitor 46 as an alternate location.

FIG. 5 discloses a schematic diagram of a light emitting device 58 forLED circuit drivers according to an embodiment of the invention. Thedevice 58 includes the device 40 as disclosed in FIG. 4 integrated intoa package as disclosed in the device 26 in FIG. 2. The device 58provides power connection leads for connecting to an AC driver 38 asdisclosed in FIG. 3.

FIG. 6 discloses a diagram of a light emitting device 64 for coupling toan LED circuit driver according to an embodiment of the invention. Thedevice 64 includes a first series string of LEDs 66 connected to asecond series string of LEDs 68 in opposing parallel configuration, acapacitor 70 connected in series between a first junction 72 of theopposing parallel series string of LEDs and a first power connection 74,and a second power connection 76 connected to a second junction 78 ofthe opposing parallel series string of LEDs. A diode may be used inplace of one or more LEDs 66 and one or more of LEDs 68 and the LEDs 66and 68 are integrated into a package 80 as described in the package 30disclosed in FIG. 2 along with capacitor 70.

FIG. 7 discloses a diagram of a light emitting device 82 for AC driveaccording to an embodiment of the invention. The device 82 includes afirst series string of LEDs 84 connected to a second series string ofLEDs 86 in opposing parallel configuration, a capacitor 88 connected inseries between a first junction 90 of the opposing parallel seriesstring of LEDs and a first power connection 92, and a resistor 94connected in series between a second junction 96 of the opposingparallel series string of LEDs and a second power connection 98. A diodemay be used in place of one or more LEDs 84 and one or more of LEDs 86and the LEDs 84 and 86 are integrated into a package 100 as described inthe package 30 disclosed in FIG. 2 along with capacitor 88 and resistor94. The resistor 94 may be put in series on either end of the capacitor88 as an alternate location.

FIG. 8 discloses a diagram of a light emitting device 102 according toan embodiment of the invention. The device 102 includes a first seriesstring of LEDs 104 connected to a second series string of LEDs 106 inopposing parallel configuration. A first power connection 108 isconnected to a first junction 110 of the opposing parallel series stringof LEDs and a second power connection 112 is connected to a secondjunction 114 of the opposing parallel series string of LEDs. A diode maybe used in place of one or more LEDs 104 and one or more of LEDs 106 andthe LEDs 104 and 106 are integrated into a package 118 as described inthe package 30 disclosed in FIG. 2.

FIG. 9 discloses a circuit diagram of a light emitting device 120according to an embodiment of the invention. The device 120 is similarto the device disclosed in FIG. 5 and includes a second series resistor122 that can be placed in series on either side of the first capacitor46.

FIG. 10 discloses a diagram of a light emitting device 124 according toan embodiment of the invention. The device 124 is similar to the devicedisclosed in FIG. 2 and includes a second series capacitor 126 connectedin series between the junction 128 of the opposing parallel LEDs and apower connection 130.

FIG. 11 discloses a diagram of a light emitting device 130 according toan embodiment of the invention. The device 130 has a matrix ofindividual light emitting devices 10 as described in FIG. 1 integratedinto a package 132 similar to package 30 as described in FIG. 2.

FIG. 12 discloses a diagram of a light emitting device 134 according toan embodiment of the invention. The device 134 has a matrix ofindividual light emitting devices 40 as described in FIG. 4 integratedinto a package 136 similar to package 30 as described in FIG. 2.

FIG. 13 discloses a diagram of a light emitting device 138 according toan embodiment of the invention. The device 138 has a matrix ofindividual sets of 2 opposing parallel light emitting devices 140 witheach set having an individual series resistor to connect to a firstpower connection 140 and a capacitor 146 connected in series between asecond power connection and the matrix of devices 140. The capacitor 146may alternately be in series between the first power connection 144 andall resistors 142. The matrix of devices 140, resistors 142 andcapacitor 146 are integrated into a package 150 similar to package 30 asdescribed in FIG. 2.

FIG. 14 discloses a diagram of a light emitting device 152 according toan embodiment of the invention. The device 152 includes another versionof a series opposing parallel LED matrix 154 and a capacitor 156connected in series between a first junction 158 of the opposingparallel LED matrix 154 and a first power connection, and a second powerconnection 162 connected to a second junction 164 of the opposingparallel LED matrix. A first power connection 108 is connected to afirst junction 110 of the opposing parallel series string of LEDs and asecond power connection 112 is connected to a second junction 114 of theopposing parallel series string of LEDs. A diode may be used in place ofone or more LEDs 104 and one or more of LEDs 106 and the LEDs 104 and106 are integrated into a package 118 as described in the package 30disclosed in FIG. 2.

FIG. 15 discloses a schematic diagram of a light emitting device 300according to an embodiment of the invention. Device 300 includes bridgerectifier circuit 302 having diodes 304 a-304 d with at least one LEDconnected across the output of the rectifier circuit, shown as LED 306.While inputs 308 and 310 of the bridge rectifier may be provided fordirect connection to an AC power supply, it is contemplated by theinvention that one input, shown as input 310, may have a capacitor(shown as capacitor 312) or a resistor (shown in FIG. 18 as resistor313) connected in series in order to control and limit the currentpassing through the at least one LED. Additionally, capacitor 314 may beconnected across the rectifier inputs to protect against voltage spikes.

FIGS. 16 and 18 each disclose a schematic diagram of a light emittingdevice 316 and 332 for an LED circuit driver according to an embodimentof the invention. The device 316 includes the device 300 as disclosed inFIG. 15 (with additional LEDs 306 added in series) mounted on aninsulating substrate 318 such as, but not necessarily, ceramic orsapphire, and forming an LED package 320 that may be various sizes;materials and designs based of product specifications or on printedcircuit board material. As shown in FIG. 16, The device 316, 332provides power connection leads 322 and 323 and may have a first oradditional lens that may be made of a plastic, polymer or other materialused for light dispersion and the lens may be coated or doped with aphosphor or nano-particle that would produce a change in the color orquality of light emitted from device 300 through the lens. LED package320 may include rectifier 302 to drive LEDs 306. Rectifier 306 may bemounted on insulating substrate 318 along with any LEDs. As should beappreciated by those having ordinary skill in the art, it iscontemplated by the invention that any diode or LED may be swapped forthe other within the package so long as the package includes at leastone LED to emit light when in operation. Any capacitors 312, 314 orresistors 313 included in the light emitting devices may like wise bemounted on substrate 318 and included in LED package 320.

Rather than be packaged together and mounted on a single substrate, andno matter whether the LEDs and diodes are integrated into a singlepackage or are discrete individual LEDs and/or diodes wire-bondedtogether, as disclosed in FIG. 17 rectifier 302 may be discretelypackaged separate from any discrete LED packages 324 where discrete LEDpackage 324 includes one LED 306 or multiple LEDs connected in series orparallel. Rectifier 302 may be packaged into rectifier package 326 forplug and use into a light system, or alternatively may be included aspart of a driver used to drive the series LEDs. When packaged separate,package 326 may be provided with input power connections 328 and 329which to connect the inputs of the rectifier to an AC power supply. Inorder to connect to one (or more) single or series LEDs and providepower thereto, package 326 may also be provided with output powerconnections 330 and 331 which may connect to LED package inputs 334 and335. Any capacitors 312, 314 or resistors 313 included in the lightemitting devices may like wise be mounted on substrate 316 and includedin rectifier package 326.

Regardless of whether rectifier 302 and LEDs 306 are integrated ormounted in a single package or are discretely packaged and connected, inorder to drop higher voltages any number of LEDs may be connected inseries or parallel in a device to match a desired voltage and lightoutput. For example, in a lighting device that is run off of a 120 Vsource and contains LEDs having a forward operating voltage of 3V eachconnected to a bridge rectifier having diodes also having a forwardoperating voltage of 3V each, approximately 38 LEDs may be placed inseries to drop the required voltage.

FIG. 19 discloses an embodiment of an LED lighting device encapsulatedin a housing. As shown in FIG. 19, LED device 336 may include a housing338 encapsulating at least one bridge rectifier 340, at least one LEDcircuit 342 connected across the output of the bridge rectifier. Device334 includes first power connection lead connected 344 to a first inputof the rectifier 346 and a second power connection lead 348 connected toa second input of the rectifier 350. At least a portion of each powerconnection is contained within the housing while at least a portion ofeach power connection extends beyond the housing to allow device 336 toconnect to an AC power source. Rectifier 340 and LED circuit 342 may beconnected, assembled, and/or packaged within housing 336 using any ofthe methods described in conjunction with FIGS. 15-18 or any other meansknown in the art. It should be appreciated by those having ordinaryskill in the art that the devices and packages described in FIGS. 2, 3,and 5-14 may likewise incorporate a housing to encapsulate any deviceand/or package therein.

FIG. 20 discloses a schematic diagram of a lighting system 168 accordingto an embodiment of the invention. The device 168 includes a pluralityof devices 26 as described in FIG. 2 connected to a high frequencyinverter AC drive Method 170 as described in FIG. 3 which in thisexample provides a relatively constant 12V AC source at a relativelyconstant frequency of 50 Khz to the devices 26. Each or some of thedevices 26 may have integrated capacitors 172 of equal or differentvalues enabling the devices 26 to operate at different drive currents174 from a single source AC drive Method.

FIG. 21 discloses a schematic diagram of a lighting system 176 accordingto an embodiment of the invention. The lighting system 176 includes aplurality of devices 178, 180 and 182 each able to have operate atdifferent currents and lumens output while connected directly to thetransformer 184 output of a fixed high frequency AC drive Method 186.

Any of the aforementioned AC drive methods may likewise be used with thedevices embodied in FIGS. 15-19.

For example, FIG. 22 discloses a schematic diagram of a lighting system400 according to an embodiment of the invention. System 400 includes aplurality of devices 316, 332 as described in FIGS. 16 and 18 connectedto a high frequency inverter AC drive Method 170 similar to thatdescribed in FIGS. 3 and 20 which provides a relatively constant 12V ACsource at a relatively constant frequency of 50 Khz to the devices 316,332. Each or some of the devices 316, 332 may have integrated capacitors312, 314 and resistors 313 of equal or different values enabling thedevices 300 to operate at different drive currents from a single sourceAC drive Method. As should be appreciated by those having ordinary skillin the art, while the example of 12V AC at 50 Khz is given herein, it iscontemplated by the invention that any voltage at substantially anyfrequency may be provided by the driver by utilizing a propertransformer and/or inverter circuit.

Similarly, AC drive Method 186 may be utilized may be used with a singleor plurality of devices 214 as disclosed in FIG. 23. As with theembodiment shown in FIG. 21, each device 316, 332 may be connecteddirectly to transformer 184 output to receive a substantially fixedfrequency voltage.

FIG. 24 discloses an embodiment of the invention where AC drive Method186 is provided to a rectifier and LED series strings are discretelypackaged. As previously disclosed, rectifier 302 may be discretelypackaged in a rectifier package 326, separate from both AC drive Method186 (or alternatively AC drive Method 170) and discrete LED packages324, or alternatively may be included in AC drive Method 186.

FIG. 25 discloses another schematic view diagram of a light emittingdevice 188 identical to the device 130 disclosed in FIG. 11 andintegrated into a package 30 as described in FIG. 2 for an AC driveMethod according to an embodiment of the invention. The device 188includes the device 130 as disclosed in FIG. 11 mounted on an insulatingsubstrate 28 such as but not necessarily ceramic or sapphire andintegrated into an LED package 30 that may be various LED package sizes;materials and designs based of product specifications or on printedcircuit board material. The device 188 provides power connection leads190 and 192 and may have a first or additional lens 194 that may be madeof a plastic, polymer or other material used for light dispersion andthe lens may be coated or doped with a phosphor or nano-crystals thatwould produce a change in the color or quality of light emitted from thedevice 130 through the lens 194. The device 130 has a matrix of devices10. The power connection opposite the capacitors 16 within the device130 and part of each device 10 is connected to a power connection 196that is connected to a solderable heat sinking material 198 andintegrated into the package 30. The power connection 196 connected tothe heat sink 198 may be of a heavier gauge within the device 130 or 188than other conductors. The schematic view of the device 188 provides aside view of the package 30 and an overhead view of the device 130 inthis FIG. 25.

FIG. 26 discloses another schematic view diagram of a light emittingdevice 198 similar to the device 188 described in FIG. 25 with adifferent light emitting device 200 identical to the device 136disclosed in FIG. 12 and integrated into a package 30 as described inFIG. 2 for an AC drive Method according to an embodiment of theinvention. The device 198 includes a reflective device integrated intothe package 30 for optimized light dispersion. The light emitting device200 may be facing down towards the reflector 202 and opposite directionof light output from the lens 194 if the reflector 202 is integratedinto the package 30 properly for such a design.

FIG. 27 discloses another schematic view diagram of a light emittingdevice 500 similar to that shown in FIG. 24 according to an embodimentof the invention. The device 500 includes the devices 316, 332 similarto those disclosed in FIGS. 16 and 18, mounted on an insulatingsubstrate 318 such as but not necessarily ceramic or sapphire andintegrated into an LED package 320 that may be various LED packagesizes; materials and designs based of product specifications or onprinted circuit board material. The device 500 provides power connectionleads 502 and 503 which connect to package power connect leads 322 and323 and may have a first or additional lens 504 that may be made of aplastic, polymer or other material used for light dispersion and thelens may be coated or doped with a phosphor or nano-crystals that wouldproduce a change in the color or quality of light emitted from thedevice through the lens 504. Power connection 322 may be connected toheat sink 506 and may be of a heavier gauge within the device than otherconductors.

FIG. 28 discloses another schematic view diagram of a light emittingdevice 508 similar to that shown in FIG. 26. Device 508 is contemplatedfor use in embodiments where the rectifier is discretely packaged orincluded as part of AC drive Method 170 or 186. In device 508, powerconnection leads 510 and 511 connect to the outputs of rectifier 302(not shown) to provide power to LED packages 324.

FIG. 29 shows a block diagram of an LED circuit driver 204 having a highfrequency inverter 206 stage that provides a relatively constant voltageand relatively constant frequency output. The high frequency inverter206 stage has an internal dual half bridge driver with an internal orexternal voltage controlled oscillator that can be set to a voltage thatfixes the frequency. A resistor or center tapped series resistor diodenetwork within the high frequency inverter 206 stage feeds back avoltage signal to the set terminal input of the oscillator. An ACregulator 208 senses changes to the load at the output lines 210 and 212of the inverter 206 and feeds back a voltage signal to the inverter 208in response changes in the load which makes adjustments accordingly tomaintain a relatively constant voltage output with the relativelyconstant frequency output.

FIG. 30 shows a schematic diagram of an LED circuit driver 214 having avoltage source stage 216, a fixed/adjustable frequency stage 218, an ACvoltage regulator and measurement stage 220, an AC level responsecontrol stage 222, an AC regulator output control stage 224 and a driveroutput stage 226.

FIG. 31 shows a schematic diagram of the voltage source stage 216described in FIG. 20. The voltage source stage 216 provides universal ACmains inputs 228 that drive a diode bridge 230 used to deliver DC to theLED circuit driver system 214. Direct DC could eliminate the need forthe universal AC input 228. Power factor correction means 232 may beintegrated into the LED circuit driver 216 as part of the circuit. Thevoltage source stage 216 includes a low voltage source circuit 234 thatmay include more than one voltage and polarity.

FIG. 32 shows a schematic diagram of the fixed/adjustable frequencystage 218 as described in FIG. 20. The fixed/adjustable frequency stage218 includes a bridge driver 236 that may include an integrated orexternal voltage controlled oscillator 238. The oscillator 238 has a setinput pin 240 that sets the frequency of the oscillator to a fixedfrequency through the use of a resistor or adjustable resistor 242 toground. The adjustable resistor 242 allows for adjusting the fixedfrequency to a different desired value through manual or digital controlbut keeps the frequency relatively constant based on the voltage at theset terminal 240.

FIG. 33 is a schematic diagram of the AC voltage regulator with voltagemeasurement stage 220 as described in FIG. 20. The AC voltage regulatorwith voltage measurement circuit 220 monitors the voltage at the driveroutput 226 as shown in FIG. 20 and sends a voltage level signal to theAC level response control stage 222 as shown in FIG. 20.

FIG. 34 is a schematic diagram of the AC level response control 228stage. The AC level response control stage 228 receives a voltage levelsignal from the AC voltage regulator with voltage measurement circuit220 as shown in FIG. 23 and drives the AC regulator output control stage224 as shown in FIG. 20.

FIG. 35 is a schematic diagram of the AC regulator output control stage230. The AC regulator output control stage 230 varies the resistancebetween the junction of the drive transistors 232 and the transformerinput pin 234 of the driver output 226 as shown in FIG. 26. The ACregulator output control stage 230 is a circuit or component such as butnot necessarily a transistor, a voltage dependent resistor or a currentdependent resistor circuit having a means of varying its resistance inresponse to the voltage or current delivered to it.

FIG. 36 is a schematic diagram of the driver output stage 226. Thedriver output stage 226 includes drive transistors 232 and thetransformer 236 that delivers an AC voltage output 238 to LED circuitsat a relatively constant voltage and frequency.

FIGS. 37 and 38 discloses a circuit 1104 to illustrate another aspect ofthe invention. Accordingly, an alternating electric field is provided toa first transmission conductor by a signal generator 1102 and a secondtransmission conductor is provided by an antenna 1108 (see FIG. 37) orwire 1124 (see FIG. 38) that is connected to a relatively less positiveside 1114-1122 within the directional circuit 1110. A difference in DCpotential between a relatively more positive side 1112 within thedirectional circuit, and relatively less positive side 1114-1122 isprovided. Another aspect of the invention is sensing proximity withimpedance changes within the directional circuits described herein (asit could be with any embodiment disclosed herein) by approaching any ofthe directional circuits or transmission conductors (also any of whichare described herein), for example approaching 1108 (shown in FIG. 37)and/or 1124 (as shown in FIG. 38) with a conductive substance such as aperson or metallic material thereby changing the circulation of currentflow within the directional circuit by changes in impedance through thecapacitance of the conductive substance.

FIGS. 39, and 40-41 disclose another embodiment of the invention havinga directional organic light emitting diode (“OLEO”) circuit 1154 thatincludes a first diode D1 1156, a second diode D2 1158, and an OLED1157. The first diode D1 1156 has an anode and the second diode D2 1158has a cathode, which are commonly connected to a input transmissionconductor 1160. The cathode of diode D1 1156 is connected to therelatively more positive side 1162 anode of an OLED 1157 while the anodeof diode D2 11 is connected to the relatively less positive side cathode1164 of the OLED 1157 to form the loop circuit 1154 among the diodes D1,D2 and the OLED 1157. The directional OLEO circuit 154 is a loop circuitwhich includes one or more circuit elements (e.g. diodes or OLEDs 1156,1157 and 1158) causing the loop circuit to be asymmetric to currentflow. Circuit element 1157 is an OLED. The directional OLEO circuit 1154does not have a continuous conductive path to earth ground, or batteryground. The directional OLEO circuit 1154 develops a DC potential inresponse to a alternating electric field imposed on input 1160. Thedirectional OLEO circuit 1154 is self referencing between a relativelyhigh potential output and a relatively lower potential output. Thedirectional OLEO circuit 1154 has a resistance, inductance andcapacitance that is responsive to the voltage and frequency of thealternating electric field. The directional OLEO circuit 1154 hastransmission conductors 1166,1168 connected to the directional OLEOcircuit 1154.

FIG. 40 discloses a circuit 1182 with the same embodiment of theinvention shown in FIG. 39 (see FIG. 39) encasing the directional OLEOcircuit 1154 within a package 1163.

FIG. 41 discloses a circuit 1184 with the same embodiment of theinvention shown in FIG. 39 (see FIG. 39) with a second transmissionconductor 1185 providing an input within the directional circuit 1184 ata point other than the input of the first transmission conductor inputof 1160. The transmission conductors 1160 and 1185 (or any transmissionconductors described herein) can act as an antenna and cause thedirectional OLEO circuit 1184 to react to the proximity of conductivesubstances near the transmission conductors 1160 and 1185. In preferredembodiments, the circuits disclosed in FIGS. 39-41 and 43 below may beconnected to ground through capacitance at a point within thedirectional circuit such as transmission conductor 1185 (e.g. FIG. 41).This ground connection seems to provide increased circulation current,as it is noted that the OLEDs get brighter for a given alternatingelectromagnetic source.

FIG. 42 discloses a circuit 1226 identical to circuit 1210 but that thecircuit has a first transmission conductor 1228 and a secondtransmission conductor 1230. Each transmission conductor 1228,230 can bedriven with an alternating electric field and can cause the circuit 1226to react to the proximity of a conductive substance that approaches thetransmission conductors 1228 and 1230 with only one or both conductorsbeing driven.

FIG. 43 discloses another embodiment of the invention having adirectional organic light emitting diode (“OLEO”) circuit 1170 thatincludes a first OLEO 1172, a second OLEO 1174, and a third OLEO 1176.The first OLEO 1172 has an anode and the third OLEO 1176 has a cathode,which are commonly connected to an input transmission conductor 1178having AC signal source from a signal generator 1180. The cathode of thefirst OLEO 1172 is connected to the anode of the second OLEO 1174 whilethe cathode of the second OLEO 1174 is connected to the anode of thethird OLEO 1176 to form the loop circuit 1170 among the OLEDs 1, 2 and 3(1172-1176). The directional OLEO circuit 1170 can be designed with morethan 3 OLEDs.

FIG. 44 discloses a preferred circuit 2010 according to the invention.The circuit 2010 includes a first source for providing an alternatingelectric field. The source may be 120V or 240V line power, RF energy orthe output of a standard AC signal generator such as generator 2012 ofFIG. 44. This generator 2012 may produce its signal with reference toground as indicated in FIG. 44. Circuit 2010 also discloses adirectional circuit 2014 connected to the generator 2012 by atransmission conductor 2016. According to the invention the conductor2016 may be any form of conventional conductive path whether twistedwire bundles, single wires, etc. The point is that the transmissionconductor 2016 provides a single transmission path to the directionalcircuit 2014. Important to the invention is the fact that there is noconductive return path provided back from the directional circuit 2016to the generator 2012.

In the broad sense, the directional circuit 2014 is a loop circuit whichincludes one or more circuit elements causing the loop circuit to beasymmetric to current flow. Again it is important that the directionalcircuit 2014 has no continuous conductive path to earth ground, or abattery ground. As such, and as disclosed in FIG. 44 the directionalcircuit 2014 develops a DC potential across a load, such as resistor R1in response to the alternating electric field. This DC potential is notreferenced to ground but merely to the potential differences created bythe circulation of current (see FIG. 45) in the loop across the load(resistor R1 of FIG. 44). Accordingly, the DC potential is selfreferencing. As far as the resistor R1 is concerned, circuit 2010presents it with a relatively higher DC potential output at 2020 and arelatively lower potential output at 2022.

FIG. 45 discloses circuit 2010 with the load represented as a genericload 2024 (rather than resistor R1) to show the circulation path ofcurrent flow (indicated by the arrows) in any generic load circuitutilizing the DC potential of circuit 2010.

FIGS. 44 and 45 disclose that the loads connected to the directionalcircuit 2014 do not have a continuous conductive path to earth ground ora battery ground. They also disclose that the directional circuit 2014has circuit elements causing the directional circuit to be asymmetric tocurrent flow. In the preferred embodiment disclosed, these circuitelements are diodes D1 and D2. However, it is contemplated that numerousother circuit elements could provide the same functionality, inparticular, semiconductors with “pn” junctions; electrets, plasma,organic; or combinations thereof.

The circuit 2010 is preferably used for delivering power and sensingproximity. The circuit 2010 is also preferably useful in TTL logicapplications as disclosed in FIG. 46 showing a standard TTL logic outputcircuit 2026 powered by circuit 2010. In that application, the DCvoltages necessary range from 0V to +/−5V.

FIGS. 44-46 each disclose that directional circuit 2014 includes firstand second diodes D1 and D2, with D1 having an anode and diode D2 havinga cathode which are commonly connected to the transmission conductor2016. the cathode of the first diode D1 is connected to the relativelymore positive side of the load 2020 while the anode of the second diodeis connected to the relatively less positive side load 2022 to form thedirectional loop circuit among the diodes and the load.

FIG. 47 discloses a circuit 2024 according to the invention having astandard AC signal generator 2026 and a directional circuit 2028includes first and second light emitting diodes (LEDs), the first LED 1has an anode and the second LED 2 has a cathode, which are commonlyconnected to the conductor 2030 from the generator 2026. The cathode ofLED 1 is connected to the relatively more positive voltage side 2032 ofthe load 2036 while the anode of LED 2 is connected to the relativelyless positive side 2034 of the load 2036 to form the loop circuit 2028among the LEDs 1 and 2. In this embodiment the load is configured tooptimize the lumen produced by the directional circuit, for example theLEDs 1, 2 used to deliver power to the load 2036 which can be a thirdLED as shown in FIG. 48.

FIG. 48 discloses a circuit 2038 according to the invention. In thisembodiment, a generator 2040 produces an alternating electric field ontransmission conductor 2040. The conductor 2041 is connected to adirectional circuit 2042 having circuit elements causing an asymmetricalresponse to the alternating field and current flow. In particular,circuit 2042 includes three LEDs 1, 2, 3, configured to providecirculation according to the direction of the arrows (see FIG. 48). Inthis embodiment, all three LEDs 1-3 provide light as an output that canbe considered as a load. This shows that relative nature of thepositioning of elements in the various directional circuits disclosedherein according to the invention. If light is desired, then each of thediodes may be considered both loads and circuit elements which causeasymmetrical current flow. For example, FIG. 49 discloses the samecircuit 2038 with only the substitution of LEDs 1 and 3 by diodes D1 andD2. In this circuit, optimization of the light emitted by LED 2 is ofparamount concern, whereas the diodes 1, 2 provide directionality and aDC offset to the AC signal source as will be disclosed in more detailbelow. In preferred embodiments, the directional circuits, includingdirectional circuit 2014, disclosed herein throughout this invention maybe connected to ground through capacitance 2039 at a point within thedirectional circuit other than the AC signal input point 40 as shown inFIG. 49. This ground connection seems to provide increased circulationcurrent, as it is noted that the LEDs get brighter for a givenalternating electromagnetic source. The capacitor 2039 may alternativelybe placed on the other side of the AC line 2041. The capacitor is usedto drop the voltage from the AC source.

FIG. 50 discloses a circuit 2042 having an AC signal generator 2044inducing an alternating electric field onto transmission conductor 2046which is connected to a first directional circuit 2048 having LEDs 1-3.LED 2 acting as a load to circuit 2048, provides the relatively high DCpotential at point 2050 and a relatively lower DC potential at point2052 to another directional circuit 2054 comprised of LEDs 4-6. This isrepeated for another directional circuit 2056 and LEDs 7-9. Again, thecircuit components LEDs 1-9 provide both directionality and useful workas a load in the form of producing light. According to another aspect ofthe invention, the circuit 2042 discloses the multiplexing possibilitiesof the directional circuits 2048, 2052, 2056. According to anotheraspect of the invention, the circuit 2042 discloses a parallel LEDdirectional circuit.

FIG. 51 discloses a circuit 2058 to illustrate another aspect of theinvention, in particular the transmission of information or data as onemay use the terms. Accordingly, the alternating electric field isprovided (as it could be with any embodiment disclosed herein) by eitheran antenna 2060 or a signal generator 2061. The alternating signalsource is imposed on transmission conductor 2062. A directional circuit2064 is comprised of a load 2066 and two diodes D1 and D2. The circuit2058 discloses the directional DC current flow as well as an AC plus DCcurrent flow and potential indicated by “AC+DC” in FIG. 51. This DC plusAC component is important to the transmission of information or datasignals from the generators 2060, 2061.

In particular, FIG. 52 discloses a circuit 2068 having a signalgenerator 2070, a transmission conductor 2072, and a directional circuit2074. The directional circuit has asymmetrical diode elements D1 and D2and a load R1. In this and the other embodiment disclosed herein (seeFIG. 51), the directional circuit 2074 is constructed to permit a DCvoltage level to accrue on the transmission conductor 2072 along withthe AC signal to provide an offset to the signal. This offset ispreferential to the signal as the signal is ungrounded. It is believedthat this may prevent noise in the system to be added to the line 2072as a second alternating field but with reference to ground. Accordinglythe noise adds to the DC level but not to the signal level in the sameproportions.

Also as disclosed in FIG. 52, an output 2076 is provided which willtransmit the AC signals from transmission line 2072 to an information ordata signal receiver 2078 which will detect the signal riding the DClevel. The DC level can easily be distinguished and handled by such areceiver as is conventional. It should be understood that the signalreceiver 2078 may be of any conventional type of TTL logic device,modem, or telecommunications receiver and is believed to operate bestwith the preferred systems of the invention when it is not connected toearth ground or a battery ground, or a current sink or charge collector(as is the case for the working loads disclosed through out thisdisclosure).

According to another embodiment, FIG. 53 discloses another informationor data communication circuit 2080. The circuit 2080 includes a signalgenerator 2082, a transmission conductor 2084, a directional circuit2086, a data receiver 2088, and a ground switch 2090. In thisembodiment, the directional circuit 2086 provides both the DC power forthe receiver 2088, and a data signal through output 2092 connectedbetween the receiver input and the common connection between theconductor 2084 and directional circuit input to anode of diode D1 andcathode D2. In the meantime, the receiver is powered on the DC potentialdifference between D1 the relatively more positive side 2094 and D2 therelatively less positive side 2096 of the directional circuit. In thisembodiment, resistor R1 is provided according to another aspect of theinvention to regulate or select as desired the level of DC offset the ACdata signal will have at line 2092.

According to another aspect of the invention, the ground switch 2090 isprovided to provide a non-continuous connection to a circuit, such asthe ground circuit disclosed in FIG. 53, to dissipate excessiveaccumulations of charge or voltage potentials in the circuit 2080. It iscontemplated that the switch 2090 be actuated based upon a timing (suchas a pre-selected clock pulse) criteria, or by a sensor (not shown) ofan undesirable DC level developing in the circuit 2080. Once engaged,the circuit 2090 would dissipate the excess energy to a ground, ground,plane, capacitor, battery ground, or the like.

FIG. 54 discloses a circuit 2092 wherein directional circuits 2094-2100are connected through a common bus conductor 2102 to provide DC powerand signals from generator 2104 as described previously herein.

FIGS. 55 and 56 disclose a circuit 2104 to illustrate another aspect ofthe invention. Accordingly, an alternating electric field is provided toa first transmission conductor by a signal generator 2102 and a secondtransmission conductor is provided by an antenna 2108 (see FIG. 55) orwire 2124 (see FIG. 56) that is connected to a relatively less positiveside 2114-2122 within the directional circuit 2110. A difference in DCpotential between a relatively more positive side 2112 within thedirectional circuit, and relatively less positive side 2114-2122 isprovided. Another aspect of the invention is sensing proximity withimpedance changes within the directional circuits described herein (asit could be with any embodiment disclosed herein) by approaching any ofthe directional circuits or transmission conductors (also any of whichare described herein), for example approaching 2108 (shown in FIG. 55)and/or 2124 (as shown in FIG. 56) with a conductive substance such as aperson or metallic material thereby changing the circulation of currentflow within the directional circuit by changes in impedance through thecapacitance of the conductive substance.

FIG. 57 discloses a circuit 2126 to illustrate another aspect of theinvention. Accordingly, an alternating electric field is provided to atransmission conductor 2132 by a signal generator 2128 that provides afirst voltage level output equal to that provided by the signalgenerator 2128. A lump inductance 2130 is provided in series of thetransmission conductor 2132 between the signal generator 2128 anddirectional circuit 2134. The lump inductance 2130 provides an increasedvoltage level from the relatively lower voltage on the transmissionconductor 2132 at the point 2136 between the signal generator 2128 andlump inductance 2136 and a relatively higher voltage level on thetransmission conductor 2132 at the point 2138 between the lumpinductance 2130 and the directional circuit 2134 thereby providing anincrease in current flow within the directional circuit 2134 orelectromagnetic field energy radiating from the circuit 2126. The amountof current flow within the directional circuits described herein andelectromagnetic field energy external of the directional circuitsdescribed herein is dependent on the frequency of an AC signal providedto the transmission conductor 2132 (or any of which are describedherein). In preferred embodiments, the circuits disclosed in FIGS. 44-57may be connected to ground through capacitance. This ground connectionseems to provide increased circulation current, as it is noted that theLEDs get brighter for a given alternating electromagnetic source.

FIG. 58 discloses a circuit 2140 according to the invention having astandard AC signal generator 2142 and a directional circuit 2144 thatincludes first and second diodes D1, D2, the first diode D1 has an anodeand the second diode D2 has a cathode, which are commonly connected tothe transmission conductor 2146 from the generator 2142. The cathode ofdiode D1 is connected to the relatively more positive side 2148 of anorganic light emitting diode (OLED) 2152 while the anode of diode D2 isconnected to the relatively less positive side 150 of the OLED 2152 toform the loop circuit 2144 among the diodes D1, D2 and the OLED 2152.

FIGS. 59, and 61-62 disclose another embodiment of the invention havinga directional organic light emitting diode (“OLED”) circuit 2154 thatincludes a first diode D1 2156, a second diode D2 2158, and an OLED2157. The first diode D1 2156 has an anode and the second diode D2 2158has a cathode, which are commonly connected to an input transmissionconductor 2160. The cathode of diode D1 2156 is connected to therelatively more positive side 2162 anode of an OLED 2157 while the anodeof diode D2 2158 is connected to the relatively less positive sidecathode 2164 of the OLED 2157 to form the loop circuit 2154 among thediodes D1, D2 and the OLED 2157. The directional OLED circuit 2154 is aloop circuit which includes one or more circuit elements (e.g. diodes orOLEDs 2156, 2157 and 2158) causing the loop circuit to be asymmetric tocurrent flow. Circuit element 2157 is an OLED. The directional OLEDcircuit 2154 does not have a continuous conductive path to earth ground,or battery ground. The directional OLED circuit 2154 develops a DCpotential in response to an alternating electric field imposed on input2160. The directional OLED circuit 2154 is self referencing between arelatively high potential output and a relatively lower potentialoutput. The directional OLED circuit 2154 has a resistance, inductanceand capacitance that is responsive to the voltage and frequency of thealternating electric field. The directional OLED circuit 2154 hastransmission conductors 2166, 2168 connected to the directional OLEDcircuit 2154.

FIG. 60 discloses another embodiment of the invention having adirectional organic light emitting diode (“OLED”) circuit 2170 thatincludes a first OLED 2172, a second OLED 2174, and a third OLED 2176.The first OLED 2172 has an anode and the third OLED 2176 has a cathode,which are commonly connected to an input transmission conductor 2178having AC signal source from a signal generator 2180. The cathode of thefirst OLED 2172 is connected to the anode of the second OLED 2174 whilethe cathode of the second OLED 2174 is connected to the anode of thethird OLED 2176 to form the loop circuit 2170 among the OLEDs 1, 2 and 3(2172-2176). The directional OLED circuit 2170 can be designed with morethan 3 OLEDs.

FIG. 61 discloses a circuit 2182 with the same embodiment of theinvention shown in FIG. 59 (see FIG. 59) encasing the directional OLEDcircuit 2154 within a package 2163.

FIG. 62 discloses a circuit 2184 with the same embodiment of theinvention shown in FIG. 59 (see FIG. 59) with a second transmissionconductor 2185 providing an input within the directional circuit 2184 ata point other than the input of the first transmission conductor inputof 2160. The transmission conductors 2160 and 2185 (or any transmissionconductors described herein) can act as an antenna and cause thedirectional OLED circuit 2184 to react to the proximity of conductivesubstances near the transmission conductors 2160 and 2185. In preferredembodiments, the circuits disclosed in FIGS. 59-66 may be connected toground through capacitance at a point within the directional circuitsuch as transmission conductor 2185 (e.g. FIG. 62). This groundconnection seems to provide increased circulation current, as it isnoted that the OLEDs get brighter for a given alternatingelectromagnetic source.

FIG. 63 discloses a matrix circuit 2186 comprised of twelve circuits2154 (e.g. FIG. 61). The circuits in the matrix 2186 are connectedcommonly to a transmission conductor 2188.

FIG. 64 discloses a matrix circuit 2190 identical to matrix circuit 2186but that the circuits 2191 employ only LEDs or optionally OLEDs.

FIG. 65 discloses a matrix circuit 2192 identical to matrix circuit 2186but that the circuits 2193 in the matrix 2192 are connected commonly toone end of a lump inductance 2196 placed in series of the transmissionconductor 2194 between the signal generator 2198 and the matrix circuit.

FIG. 66 discloses a matrix circuit 2200 identical to matrix circuit 2192but that the circuits in the matrix 2200 are connected to individuallump inductances 2201-2206 which can be of equal or different values.

FIG. 67 shows a device 2482 comprising individual light emitting diodecircuits 2484 on a flexible printed circuit board having a mirror likereflective material or coating 2488 designed into or on the flexibleprinted circuit board in an area at least near the light emitting diodesfor providing more efficient light output from the circuit board areassurrounding the light emitting diodes by having the flexible printedcircuit board reflect light rather than absorb it. Power connectionpoints 2490 and 2492 are provided to the board.

FIG. 68 shows a device 2494 comprising a device 2496 identical to thedevice shown in FIG. 67 adhered to a device 2498 having a cylindricalshape for providing improved uniformity and increased angle of lightoutput from device 2496.

A circuit includes a first source for providing an alternating electricfield, a directional circuit is connected to the first source forproviding an alternating electric field by a transmission conductorthere being no conductive DC path is provided back from the directionalcircuit to the first source for providing an alternating electric field.The directional circuit being a loop circuit which includes one or morecircuit elements causing the loop circuit to be asymmetric to currentflow; the directional circuit having no continuous conductive path toearth ground, or battery ground, the directional circuit therebydeveloping a DC potential in response to the alternating electric fieldwhich is self referencing between a relatively high potential output anda relatively lower potential output. One or more loads connected to thedirectional circuit, the one or more loads also not having a continuousconductive path to earth ground or a battery ground. The load is notprovided with a continuous connection to earth ground, or batteryground. The load may be provided with a capacitive connection to earthground, or battery ground. The DC current flow within the directionalcircuit is adjustable by tuning the directional circuit to differentfrequencies of an alternating electric field thereby causing thedirectional circuit to reach a resonant state. The current flowincreases within the directional circuit and the electromagnetic fieldis concentrated within the directional circuit when the directionalcircuit is tuned to a resonant frequency. The directional circuit beingtuned out of its resonant frequency and providing a largerelectromagnetic field surrounding the exterior of the directionalcircuit enables the directional circuit to be responsive to theproximity of objects having a capacitance that enter the electromagneticfield. The directional circuit is tuned towards resonance as conductiveobjects enter the electromagnetic field of the directional circuit.

The above-described embodiments of the present invention are intended tobe examples only. Alterations, modifications and variations may beeffected to the particular embodiments by those of ordinary skill in theart without departing from the scope of the invention, which is definedby the claims appended hereto.

What is claimed is:
 1. An LED lighting system comprising: at least oneLED circuit having at least two LEDs, wherein the at least two LEDs inthe at least one LED circuit are the same or different colors; an LEDdriver; wherein the LED driver has an input voltage and an outputvoltage, the LED driver having an input of a first voltage and a firstfrequency from a mains power source and providing a DC voltage output;wherein the LED driver includes a voltage measurement circuit thatmonitors the DC voltage output; wherein the LED driver includes avoltage regulator that regulates the output voltage at a relativelyfixed level and adjusts the output voltage, based upon the output of thevoltage measurement circuit, to maintain the relatively fixed outputvoltage level when additional LED circuits are added to the LED lightingsystem so long as the total output wattage of the driver is notexceeded; and wherein the LED lighting system has integrated circuitrythat allows for the light output of the lighting system to be dimmable.2. The LED lighting system of claim 1, further comprising: a switch withat least three positions for adjusting the relatively fixed level of theoutput voltage of the LED driver and the brightness of the at least oneLED circuit.
 3. The LED lighting system of claim 1, wherein the LEDdriver includes a field effect transistor.
 4. The LED lighting system ofclaim 1, wherein the LED lighting system includes an active currentlimiting device connected to the LED driver.
 5. The LED lighting systemof claim 1, wherein the at least two LEDs are mounted on a substratethat is sufficiently flexible to be wrapped around a cylindrical object.6. The LED lighting system of claim 1, wherein the at least one LEDcircuit is configured to change at least one of a brightness, a color,or a quality of light in response to a switch.
 7. An LED lighting devicecomprising: at least one LED circuit having at least two LED packagesconnected in series, wherein each LED package has at least two LED chipsconnected in series and mounted on a glass substrate; a bridge rectifierconnected to an AC mains voltage, wherein the bridge rectifier providesa rectified DC output; an LED driver, wherein an input of the LED driveris connected to the bridge rectifier and an output of the LED driver isconnected to the at least one LED circuit; a capacitor connected to thebridge rectifier or the LED driver, wherein the capacitor smooths theoutput of the LED driver before the output of the LED driver is providedto the at least one LED circuit; wherein the LED lighting device ispackaged in a bulb; and wherein the LED lighting device is configured tobe connected to a socket.
 8. The LED lighting device of claim 7, whereinthe substrate is sufficiently flexible to be wrapped around acylindrical object.
 9. The LED lighting device of claim 7, wherein theat least one LED is coated with a substance to change a color of lightemitted by the at least one LED.
 10. The LED lighting device of claim 7,wherein the substrate is made of sapphire.
 11. An LED lighting systemcomprising: an LED driver, the LED driver having an input for receivinga first AC voltage and having an output of a second voltage, wherein thesecond voltage is relatively lower than the first AC voltage and whereinthe LED driver includes: a capacitor, a voltage measurement circuit thatmonitors the second voltage, and a voltage regulator that regulates thesecond voltage at a relatively fixed level and that adjusts the secondvoltage, based upon the output of the voltage measurement circuit, tomaintain the relatively fixed output voltage level when LED circuits areadded to and removed from the LED lighting system so long as the totaloutput wattage of the driver is not exceeded; and at least one LEDcircuit connected to the output of the LED driver.
 12. The LED lightingsystem of claim 11, wherein the second voltage is either a DC voltage ora rectified AC voltage that is a lower voltage than the first AC voltageof the input received by the LED driver.
 13. The LED lighting system ofclaim 11, wherein the LED driver is configured for receiving one of atleast two different input voltages.
 14. The LED lighting system of claim13, wherein the at least one LED circuit includes a semiconductor devicefor varying or diverting a current of the output of the LED driver. 15.The LED lighting system of claim 14, wherein the semiconductor device isan additional driver.
 16. The LED lighting system of claim 15, whereinthe additional driver is a transistor.
 17. The LED lighting system ofclaim 14, wherein the semiconductor device is a current limiting diode.18. The lighting system of claim 14, wherein the LED driver includes aninternal dual half bridge driver.
 19. The lighting system of claim 18,wherein the internal dual half bridge driver is coupled to a controllerthat controls an output of the dual half bridge driver.
 20. The lightingsystem of claim 11, wherein the LED driver includes a step-downtransformer.